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RESEARCH ARTICLE

Genetic variation within and between subpopulations of the Australian Merino breed

Andrew A. Swan A C D , Daniel J. Brown A C and Julius H. J. van der Werf B C
+ Author Affiliations
- Author Affiliations

A Animal Genetics and Breeding Unit (AGBU*), University of New England, Armidale, NSW 2351, Australia.

B School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.

C The CRC for Sheep Industry Innovation, University of New England, Armidale, NSW 2351, Australia.

D Corresponding author. Email: andrew.swan@une.edu.au

Animal Production Science 56(1) 87-94 https://doi.org/10.1071/AN14560
Submitted: 8 May 2014  Accepted: 10 September 2014   Published: 19 February 2015

Abstract

Genetic variation within and between Australian Merino subpopulations was estimated from a large breeding nucleus in which up to 8500 progeny from over 300 sires were recorded at eight sites across Australia. Subpopulations were defined as genetic groups using the Westell–Quaas model in which base animals with unknown pedigree were allocated to groups based on their flock of origin if there were sufficient ‘expressions’ for the flock, or to one of four broad sheep-type groups otherwise (Ultra/Superfine, Fine/Fine-medium, Medium/Strong, or unknown). Linear models including genetic groups and additive genetic breeding values as random effects were used to estimate variance components for 12 traits: yearling greasy and clean fleece weight (ygfw and ycfw), yearling mean and coefficient of variation of fibre diameter (yfd and ydcv), yearling staple length and staple strength (ysl and yss), yearling fibre curvature (ycuv), yearling body wrinkle (ybdwr), post-weaning weight (pwt), muscle (pemd) and fat depth (pfat), and post-weaning worm egg count (pwec). For the majority of traits, the genetic group variance ranged from approximately equal to two times larger than the additive genetic (within group) variance. The exceptions were pfat and ydcv where the genetic group to additive variance ratios were 0.58 and 0.22, respectively, and pwec and yss where there was no variation between genetic groups. Genetic group correlations between traits were generally the same sign as corresponding additive genetic correlations, but were stronger in magnitude (either more positive or more negative). These large differences between genetic groups have long been exploited by Merino ram breeders, to the extent that the animals in the present study represent a significantly admixed population of the founding groups. The relativities observed between genetic group and additive genetic variance components in this study can be used to refine the models used to estimate breeding values for the Australian Merino industry.

Additional keywords: random genetic groups, sheep.


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